Connecting element

ABSTRACT

The application relates to a connecting element, in particular for connecting vessels and for producing a fluidic connection between vessels or elements joined to the connecting element. The invention also relates to an elastic spring element as a valve element.

TECHNICAL FIELD

The invention relates to a connecting element, in particular forconnecting vessels and for producing a fluidic connection betweenvessels or elements joined to the connecting element. The invention alsorelates to an elastic spring element as a valve element.

PRIOR ART

In particular in the medical sphere of use, it is known in the prior artthat liquid solutions or drugs are collected from a storage vessel bymeans of syringes and administered to patients. For this purpose, it isknown that the liquid is collected by the syringe directly via thehollow needle of the syringe and is subsequently administered directlyto the patient.

It is also known that a connecting element is placed onto the storagevessel, and the syringe can then be attached to said connecting elementin order to draw the liquid out of the storage vessel into the syringe.When the syringe is subsequently pulled out therefrom again, liquid canstill escape from the syringe, which is highly disadvantageous inparticular in the case of very expensive drugs. Soiling is thereforealso possible because escaping drugs or liquids may be lost, and this isconsidered to be disadvantageous in the medical sphere or in the caresphere.

It is also known that infusion solutions in particular can be connectedto a hollow needle by means of tube lines, wherein drugs can also bemetered into such tube lines or hollow needles. This then takes placevia a connecting element which is subject to the same disadvantages asalready described above.

SUMMARY OF THE INVENTION, OBJECT, SOLUTION, ADVANTAGES

It is the object of the invention to provide a connecting element whichpermits a secure connection and, nevertheless, if nothing is connectedthereto, permits a secure and tight closure of the vessel connectedthereto. It is also the object of the invention to provide an elasticspring element as the valve element, which permits secure sealing with asimultaneous simple design.

This is achieved by the features of claim 1.

An advantageous exemplary embodiment of the invention relates to aconnecting element with a housing having a first receiving space with afirst joining element and a first shiftable valve element arrangedtherein, and having a second receiving space with a second joiningelement with a second shiftable valve element arranged therein, thefirst and the second receiving space are fluidically connected to eachother, wherein the first valve element is of elastically deformabledesign and is shiftable, and the second valve element is of elasticallydeformable design and is shiftable, wherein the first valve element isshiftable between two positions, wherein, in the first position, afluidic connection between the first receiving space and the firstjoining element is interrupted by the first valve element and, in thesecond position, a fluidic connection between the first receiving spaceand the first joining element is opened by the first valve element, andwherein the second valve element is shiftable between two positions,wherein, in the first position, a fluidic connection between the secondreceiving space and the second joining element is interrupted by thesecond valve element and, in the second position, a fluidic connectionbetween the second receiving space and the second joining element isopened by the second valve element, wherein the first valve element isformed with a duct which is closed in the first position of the firstvalve element and is opened in the second position of the first valveelement, wherein a hollow pin is arranged in the first receiving spaceand engages in the duct. A connecting element which is sealed on bothsides is thereby provided.

The object is also achieved by the features of claim 2.

An exemplary embodiment of the invention relates to a connecting elementwith a housing having a first receiving space with a first joiningelement and a first shiftable valve element arranged therein, and havinga second receiving space, the first and the second receiving space arefluidically connected to each other, wherein the first valve element isof elastically deformable design and is shiftable, wherein the firstvalve element is shiftable between two positions, wherein, in the firstposition, a fluidic connection between the first receiving space and thefirst joining element is interrupted by the first valve element and, inthe second position, a fluidic connection between the first receivingspace and the first joining element is opened by the first valveelement, wherein the first valve element is formed with a duct which isclosed in the first position of the first valve element and is opened inthe second position of the first valve element, wherein a hollow pin isarranged in the first receiving space and engages in the duct. Aconnecting element which is sealed on one side is thereby provided.

According to the invention, the housing is of at least two-part design,wherein the at least two housing parts are advantageously connected toeach other, for example, in particular, are connected to each other soas not to be releasable nondestructively. The at least two parts herecan be, for example, welded or adhesively bonded to one another. If morethan two housing parts are connected to one another, said housing partscan be welded to one another. It is also possible for only some of saidhousing parts to be welded to one another. It is possible for otherhousing parts merely to be inserted or adhesively bonded.

Furthermore, it is advantageous if the first receiving space and thesecond receiving space are formed by a first and a second housing part,wherein the first housing part form the first receiving space and thesecond receiving space, wherein the second housing part bounds the firstreceiving space in the manner of a cover. The second housing part hereis preferably a type of cover which is placed onto the other, firsthousing part and closes off or bounds a receiving space.

It is particularly advantageous if the hollow pin is inserted as a thirdhousing part into the first or the second housing part. The hollow pincan thus be inserted with a retaining plate into one of the receivingspaces and can optionally be connected to the housing part.

It is particularly advantageous if the third housing part forming thehollow pin is connected in an integrally bonded manner to the first orthe second housing part. The third housing part here can be connected toone of the other housing parts.

Alternatively, it is also advantageous if the hollow pin is formedintegrally with the first or the second housing part, for example, inparticular, is injected molded thereon. The installation complexity canthereby be reduced.

It is also advantageous if the first joining element is arranged orformed on the first housing part and the second joining element isarranged or formed on the second housing part. This has the effect thatthe two joining elements can lie opposite each other if the respectivehousing parts are correspondingly designed. This achieves a simple flowtherethrough.

It is also advantageous if the first receiving space has a circularcross section in section and is bounded by an encircling wall, whereinthe receiving space is bounded by two approximately flat, in particularupper and lower, wall regions, wherein the first joining element isarranged or accommodated on one of the two walls, in particular theupper wall, and a fluidic connection to the second receiving space isprovided in the other wall, in particular the lower wall.

It is also advantageous if the first receiving space has a circularcross section in section with outwardly protruding pockets and isbounded by an encircling wall which is changeable in radius, wherein thereceiving space is bounded by two approximately planar wall regions,such as, in particular, an upper and lower wall, wherein the firstjoining element is arranged or accommodated on one of the two walls, inparticular the upper wall, and a fluidic connection to the secondreceiving space is provided in the other wall, in particular the lowerwall. The design of the pockets permits the simple arrangement of springarms of the valve element. As a result, the position of the spring armsis relatively well defined and a secure arrangement of the spring armsis ensured even under application of force.

It is particularly advantageous if the number of pockets is greater thanor equal to the number of spring arms of a valve element inserted intothe receiving space.

It is particularly advantageous if a spring arm of the valve element isarranged in each pocket. The bearing of the spring arms is therebyunambiguously defined and no errors with regard to erroneous insertioncan occur even during the installation.

It is also advantageous if the first joining element has ahollow-cylindrical element and the first valve element has at least onecylindrical region which is accommodated in a shiftable manner in thehollow-cylindrical element. The cylindrical element here serves forsealing off or opening up an opening in the joining element.

Furthermore, it is advantageous if the first valve element has springarms protruding at the cylindrical region. The valve element can therebybe shifted counter to the restoring force of the spring arms.

It is particularly advantageous here if the spring arms protrude fromthe cylindrical region in a manner substantially corresponding to theedges of a tetrahedron. A secure positioning of the spring arms andtherefore of the valve element is thereby achieved.

It is also expedient if the protruding spring arms are designed asspring arms which are rectilinear or are kinked or curved once ormultiple times. In the case of the curved or kinked spring arms, adefined spring deflection is achieved by bending about a predeterminedbending point.

It is particularly advantageous if the spring arms of the first valveelement are arranged at an angle of 120° to one another in the planeperpendicular to the longitudinal axis of the cylindrical region.

It is also advantageous here if the spring arms have a first regionwhich is arranged at an angle of approximately 25 to 30°, preferably27°, to the plane perpendicular to the longitudinal axis of thecylindrical region.

It is also advantageous if the spring arms have a second region which isarranged at an angle of approximately 35 to 40°, preferably 37°, to theplane perpendicular to the longitudinal axis of the cylindrical region.

Furthermore, it is advantageous if the spring arms have a third regionwhich is arranged at an angle of approximately 75 to 80°, preferably77°, to the plane perpendicular to the longitudinal axis of thecylindrical region.

An advantageous defined bending behavior under load is achieved by themultiple kinking.

It is particularly advantageous if, in the event of a load being appliedto the cylindrical region, the spring arms are deformed in an arcuatemanner such that the cylindrical region substantially carries out anaxial movement.

According to the invention, it is expedient if the duct of the valveelement is open on one side and is designed to be closeable on theopposite side with a closeable and openable slot. A slot here is, forexample, a longitudinal slot or a cross- or star-shaped slot or a slotformed in some other way.

It is advantageous here if, in the unloaded state of the valve element,the hollow pin only partially engages, if at all, in the duct and doesnot act upon the slot in the closed state, and therefore the duct isclosed.

It is also advantageous if, in the loaded state of the valve element,the hollow pin virtually completely engages in or reaches through theduct and acts upon or pushes through the slot, and therefore the duct isopened.

According to the invention, it is expedient if the second joiningelement has a hollow-cylindrical element.

It is advantageous if the second joining element has ahollow-cylindrical element and the second valve element has at least onecylindrical region which is accommodated in a shiftable and/ordeformable manner in the hollow-cylindrical element. By means of anapplication of force to the second valve element, the latter can beshifted and/or deformed in a receptacle of the second joining element inorder to open or to close a fluidic connection.

It is advantageous here if the second valve element has spring armsprotruding at the cylindrical region. The second valve element canthereby is shiftable counter to the restoring force of the spring arms.The second spring element is also elastically deformable because of itsinherent elasticity counter to the restoring force.

It is advantageous here if the spring arms protrude from the cylindricalregion in a manner substantially corresponding to the edges of atetrahedron.

The protruding spring arms can also be designed as spring arms which arerectilinear or are kinked or curved once or multiple times.

It is particularly advantageous if the spring arms of the second valveelement are arranged at an angle of 120° to one another in the planeperpendicular to the longitudinal axis of the cylindrical region.

Furthermore, it is advantageous if the spring arms have a first regionwhich is arranged inclined at an angle of approximately 35 to 55°, inparticular approximately 45°, to the plane perpendicular to thelongitudinal axis of the cylindrical region.

It is also advantageous if the spring arms have a second region which isarranged in a plane perpendicular to the longitudinal axis of thecylindrical region.

Furthermore, it is advantageous if, in the event of a load being appliedto the cylindrical region, the spring arms are deformed in an arcuatemanner such that the cylindrical region substantially carries out anaxial movement.

It is also advantageous if the cylindrical region of the second valveelement bends under a load. As a result, the second cylindrical regioncan lift off from a sealing surface of the second receiving space andopen up a fluidic connection.

It is also expedient if the end side of the second receiving space has aradially inwardly directed constriction against which the second valveelement is positioned in a sealing manner in the unloaded state.

The object is also achieved by the features of claim 36.

An exemplary embodiment of the invention relates to an elastic springelement with a cylindrical body and spring arms protruding therefrom,wherein the spring element is manufactured from an elastic material.

It is advantageous here if the protruding spring arms are designed asspring arms which are kinked and/or curved once or multiple times.

It is also expedient if the spring arms of the first and/or second valveelement are arranged at an angle of 120° to one another in the planeperpendicular to the longitudinal axis of the cylindrical region.

It is expedient here if the spring arms have a first region which isarranged at an angle of approximately 35 to 55° to a plane perpendicularto the longitudinal axis of the cylindrical region.

It is also advantageous if the spring arms have a second region which isarranged in a plane perpendicular to the longitudinal axis of thecylindrical region.

It is also advantageous if the cross section of the spring arm is ofround or oval or polygonal design.

It is also advantageous if the cross section of the spring arm is oval,wherein the cross section has a smaller diameter in a plane through themean perpendicular of the spring element than in the directionperpendicular thereto.

It is also advantageous if the cylindrical body has an encirclingsealing lip or an encircling sealing region at an end region which isarranged opposite the spring arms.

It is also advantageous if the sealing lip or the sealing region isdesigned as an encircling step.

Further advantageous refinements are described by the description belowof the figures and by the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in more detail below on the basis of at leastone exemplary embodiment and with reference to the drawings, in which:

FIG. 1 shows a section of a first exemplary embodiment of a connectingelement according to the invention,

FIG. 2 shows a perspective view of a housing part,

FIG. 3 shows a perspective view of a valve element,

FIG. 4 shows a perspective view of a housing part,

FIG. 5 shows a perspective view of a valve element,

FIG. 6 shows a perspective view of a housing part,

FIG. 7 shows a view of the connecting element from above,

FIG. 8 shows a section of a second exemplary embodiment of a connectingelement according to the invention,

FIG. 9 shows a perspective view of a housing part,

FIG. 10 shows a perspective view of a valve element,

FIG. 11 shows a perspective view of a housing part,

FIG. 12 shows a view of the connecting element from above,

FIG. 13 shows a perspective view of an adapter element,

FIG. 14 shows a perspective view of an opening in the hollow pin,

FIG. 15 shows a perspective view of an opening in the hollow pin,

FIG. 16 shows a perspective view of an opening in the hollow pin, and

FIG. 17 shows a section of a further exemplary embodiment of aconnecting element according to the invention.

PREFERRED EMBODIMENT OF THE INVENTION

FIGS. 1 to 7 show a first exemplary embodiment of a connecting element 1according to the invention in various illustrations. FIG. 1 shows theconnecting element 1 in section, FIGS. 2 to 6 show an explodedillustration in a perspective view, and FIG. 7 shows a top view.

The connecting element 1 is designed with a housing 2. The housing 2consists of at least two housing parts, wherein three housing parts 3,4, 5 are provided in this exemplary embodiment. The housing parts 3, 4are formed connected to each other, for example welded to each other.The housing part 5 is inserted into the housing part 3 and is alsoconnected there to the housing part 3.

The first housing part 3 has a base 6 with an encircling wall 7protruding at an angle of 90° thereon. The wall 7 here is orientedsubstantially axially.

The base 5 is provided with the joining element 8. For this purpose, thejoining element 8 is attached as a joining branch to the base 6. Saidjoining element is advantageously connected or formed integrally withthe base 6. An element which is to be connected can be connected herefor example screwed, to the joining element 8. For this purpose, athread 10 is provided by means of which the element to be connected canbe screwed.

The housing part 3 has a tubular region 11 which protrudes in the axialdirection from the base 6 and protrudes from the base 6 in the oppositedirection to the wall 7.

The second housing part 4 is formed in the manner of a cover with a base12, from which a joining branch 13 with a fluid opening 14 extendsupward in the axial direction. A projection 15 which engages radially onthe inside and in the axial direction in the wall 7 is provided in theopposite direction. As illustrated in FIG. 2, the projection 15 isdesigned in a segmented manner and distributed over the circumference ofthe base 12.

As can be seen in FIG. 1, the two housing parts 3, 4 are connected toeach other, for example welded, on the end side of the wall 7.Alternatively, adhesive bonding, pressing together, clipping, etc. mayalso be usable.

The housing 2 forms a first receiving space 16, wherein said receivingspace is arranged within the housing part 3 in the region closed offfrom the housing part 4. The receiving space 16 here is surrounded bythe wall 7.

According to FIGS. 1 and 6, the wall 7 is not of completely rounddesign, but rather has pockets 17 which protrude radially outward andserve for receiving spring arms of the valve element. The pockets 17here are designed as radially outwardly protruding regions of a circle,wherein the radius of the wall 7 is smaller between the pockets 17.

The third housing part 5 is arranged in the receiving space 16. Saidhousing part has a baseplate 19 and a hollow pin 20 which protrudestherefrom and has a continuous duct 21. At the upper end of the hollowpin, the pin has two opposite projections 22 which allow the duct to endtherebetween in a manner running in the lateral direction. The duct 21is open toward the second receiving space 23.

Furthermore, a valve element 18 is arranged in the receiving space 16.

The joining element 13 is provided upward on the base 12 of the housingpart 4, as already described above. If an element to be connected to thejoining element 13, such as, for example, a syringe or similar, or abranch attached thereto, is inserted or screwed into the joining element13, fluidic communication between the element to be connected and thereceiving space 16 is intended to be able to take place. If an elementto be connected is not inserted into the joining element 13, the joiningelement 13 is intended to be closed off and sealed.

This is achieved by the valve element 18. The valve element 18 has acylindrical region 24 from which spring arms protrude downward. Thecylindrical region 24 with the spring arms 25 is advantageously formedintegrally here and the spring arms 25 protrude radially outward anddownward from the cylindrical region 24 at an angle of approximately 45°to the vertical. When three spring arms are present, the spring arms 25approximately form an arrangement in accordance with an edge arrangementof a tetrahedron.

The protruding spring arms 25 are advantageously designed as spring arms25 which are rectilinear or are kinked or curved once or multiple times.In the exemplary embodiment of FIGS. 1 to 6, the spring arms 25 aredesigned to be kinked twice.

For this purpose, the spring arms 25 have a first region 26 which isarranged at an angle α1 of approximately 25 to 30°, preferably 27°, tothe plane perpendicular to the longitudinal axis of the cylindricalregion 24.

Furthermore, the spring arms 25 have a second region 27 which isarranged at an angle α2 of approximately 35 to 40°, preferably 37°, tothe plane perpendicular to the longitudinal axis of the cylindricalregion 24.

The spring arms also have a third region 28 which is arranged at anangle α3 of approximately 75 to 80°, preferably 77°, to the planeperpendicular to the longitudinal axis of the cylindrical region 24.

The cylindrical region 24 has a duct 29 which is closed at its upperend. The cylindrical region 24 has there a slot 30 which opens whendeformed.

If the slot 30 is closed, a fluidic connection between the joiningelement 13 and the receiving space 16 is prevented. If the slot 30 isopened, a fluidic connection between the joining element 13 and thereceiving space 16 is made possible.

If the valve element 18 is pressed downward in the axial direction by anelement to be connected, the hollow pin 20 engages in the duct 29 anddeforms the cylindrical region 24 such that the slot is opened.

In the positions of the valve element 15 that are shown in FIG. 1, afluidic connection between the joining element 13 and the receivingspace 16 is closed off and sealed. If an element is inserted from aboveinto the joining element 13, the cylindrical region 24 of the valveelement 18 is compressed and pushed downward, and therefore the springarms 25 are supported on the edges of the pockets 17 and are elasticallydeformed. The cylindrical region 24 is thereby shifted downward and thefluidic connection is made possible by means of slot 30 and duct 29 andthe hollow pin.

If the element to be connected is removed again from the joining element7, the elastic moldable valve element 18 relaxes again and thecylindrical region 24 is pushed upward again, and therefore the joiningelement 13 is sealed again.

The interior of the connecting element 1 is divided by the base 19. Thereceiving space 23 which is of approximately cylindrical design isarranged below the base 19. The second valve element 31 with thecylindrical region 32 and the spring arms 33 is arranged in saidreceiving space 23. The spring arms are arranged between a flank of thefirst housing part and the base 19 and support the cylindrical region 32in the axial direction. If an element to be connected is screwed intothe joining region 8, the cylindrical region 32 of the second valveelement is shifted axially upward counter to the restoring force of thespring arms 33, with the cylindrical region 32 also being deformed. Inthe process, the lower sealing region 34 is released from the encirclingbead 35 of the tubular region 11 and a fluid flow is permitted.

Preferably, the elastic elements which are provided as valve elements18, 31 consist of an elastomeric material and the housing elements 3, 4,5 consist of a non-elastomeric, but rather dimensionally stable,material, such as of thermoplastic. The element 18 and the element 31here can preferably be composed of liquid silicone rubber (LSR) orsilicone rubber crosslinking at a high temperature (HTC) or siliconerubber crosslinking at room temperature (RTC), and the housing parts 3,4, 5 can consist of acrylonitrile/butadiene/styrene (ABS), polycarbonate(PC), polypropylene (PP) or polyethylene (PE) or the like.

FIGS. 8 to 12 show a second exemplary embodiment of a connecting element101 according to the invention in various illustrations. FIG. 8 showsthe connecting element 101 in section, FIGS. 9 to 11 show an explodedillustration in a perspective view, and FIG. 12 shows a top view.

The connecting element 101 is designed with a housing 102. The housing102 consists of at least two housing parts 103, 104. The housing parts103, 104 are formed connected to each other, for example welded to eachother. Instead of an additional housing part, the hollow pin is formedintegrally with the housing part 103 in this exemplary embodiment.

The first housing part 103 has a base 106 with an encircling wall 107protruding at an angle of 90° thereon. The wall 107 here is orientedsubstantially axially.

The base 105 is provided with the joining element 108. For this purpose,the joining element 108 is attached to the base 106 as a joining branch.Said joining element is advantageously connected or formed integrallywith the base 106. An element which is to be connected can be connectedhere, for example screwed, to the joining element 108. For this purpose,a thread 110 is provided by means of which the element to be connectedcan be screwed.

The housing part 103 has a tubular region 111 which protrudes in theaxial direction from the base 106 and protrudes from the base 106 in theopposite direction to the wall 107.

The second housing part 104 is designed in the manner of a cover with abase 112, from which a joining branch 113 with a fluid opening 114extends upward in the axial direction. A projection 115 is provided inthe opposite direction, said projection engaging radially on the insideand in the axial direction into the wall 107. As illustrated in FIG. 9,the projection 115 is designed in a segmented manner and distributedover the circumference of the base 112.

As can be seen in FIG. 8, the two housing parts 103, 104 are connectedto each other, for example welded, on the end side of the wall 107.Alternatively, adhesive bonding, pressing together, clipping, etc. mayalso be usable.

The housing 102 forms a first receiving space 116, wherein saidreceiving space 116 is arranged within the housing part 103 in theregion closed off from the housing part 104. The receiving space 116 issurrounded here by the wall 107.

According to FIGS. 8 and 11, the wall 107 is not of completely rounddesign, but rather has radially outwardly protruding pockets 117 whichserve for receiving spring arms of the valve element. The pockets 117here are designed as radially outwardly protruding regions of a circle,wherein the radius of the wall 107 is smaller between the pockets 117.

A hollow pin 120 which protrudes from the base 106 and has a continuousduct 121 is accommodated in the receiving space 116. At the upper end ofthe hollow pin, the pin has two opposite projections 122 which allow theduct to end therebetween in a manner running in the lateral direction.The duct 121 is opened toward the second receiving space 123.

Furthermore, a valve element 118 is arranged in the receiving space 116.

The joining element 113 is provided upward on the base 112 of thehousing part 104, as already described above. If an element to beconnected to the joining element 113, such as, for example, a syringe orthe like, or a branch attached thereto, is inserted or screwed into thejoining element 113, fluidic communication between the element to beconnected and the receiving space 116 is intended to be able to takeplace. If an element to be connected is not inserted into the joiningelement 113, the joining element 113 is intended to be closed off andsealed.

This is achieved by the valve element 118. The valve element 118 has acylindrical region 124 from which spring arms 125 protrude downward. Thecylindrical region 124 with the spring arms 125 is advantageously ofintegral design here and the spring arms 125 protrude radially outwardand downward from the cylindrical region 124 at an angle ofapproximately 45° to the vertical. When three spring arms are present,the spring arms 125 approximately form an arrangement in accordance withan edge arrangement of a tetrahedron.

The protruding spring arms 125 are advantageously designed as springarms 125 which are rectilinear or are kinked or curved once or multipletimes. In the exemplary embodiment of FIGS. 8 to 12, the spring arms 125are designed to be kinked twice.

For this purpose, the spring arms 125 have a first region 126 which isarranged at an angle α1 of approximately 25 to 30°, preferably 27°, tothe plane perpendicular to the longitudinal axis of the cylindricalregion 124.

Furthermore, the spring arms 125 have a second region 127 which isarranged at an angle α2 of approximately 35 to 40°, preferably 37°, tothe plane perpendicular to the longitudinal axis of the cylindricalregion 124.

The spring arms also have a third region 128 which is arranged at anangle α3 of approximately 75 to 80°, preferably 77°, to the planeperpendicular to the longitudinal axis of the cylindrical region 124.

The cylindrical region 124 has a duct 129 which is closed at its upperend. The cylindrical region 124 there has a slot 130 which opens whendeformed.

If the slot 130 is closed, a fluidic connection between the joiningelement 113 and the receiving space 116 is prevented. If the slot 130 isopened, a fluidic connection between the joining element 113 and thereceiving space 116 is made possible.

If the valve element 118 is pressed downward in the axial direction byan element to be connected, the hollow pin 120 engages in the duct 129and deforms the cylindrical region 124, and therefore the slot isopened.

In the positions of the valve element 118 that are shown in FIG. 8, afluidic connection between the joining element 113 and the receivingspace 116 is closed off and sealed. If an element is inserted from aboveinto the joining element 113, the cylindrical region 124 of the valveelement 118 is compressed and pushed downward such that the spring arms125 are supported on the edges of the pockets 117 and are elasticallydeformed. As a result, the cylindrical region 124 is shifted downwardand the fluidic connection is made possible by means of slot 130 andduct 129 and the hollow pin.

If the element to be connected is removed again from the joining element107, the elastic moldable valve element 118 is relaxed again and thecylindrical region 124 is pushed upward again, and therefore the joiningelement 113 is sealed again.

The interior of the connecting element 101 is divided by the base 106.The receiving space 123, which is of approximately cylindrical design,is arranged below the base 106. A valve element is not arranged in saidreceiving space 123. If an element to be connected is screwed into thejoining region 106, there is a fluidic connection to the receiving space116.

Preferably, the elastic element which is provided as valve element 118consists of an elastomeric material and the housing elements 3, 4consist of a non-elastomeric, but rather dimensionally stable, material,such as thermoplastic. The element 118 here can preferably consist ofliquid silicone rubber (LSR) or silicone rubber crosslinking at a hightemperature (HTC) or silicone rubber crosslinking at room temperature(RTC), and the housing parts 3, 4 can consist ofacrylonitrile/butadiene/styrene (ABS), polycarbonate (PC), polypropylene(PP) or polyethylene (PE) or the like.

FIG. 13 shows a connecting element 201 which serves as an adapter part.It connects the joining elements 213 and 208 to the tubular element 211,as are also already known from the previous figures, wherein no valveelements are provided in this exemplary embodiment. If the joiningelement 213 is screwed into the joining element 8 of FIG. 1, the secondvalve element is acted upon in the axial direction by the projection 210and the fluidic connection is opened by shifting and deformation of thesecond valve element.

An arrangement of a connecting element 1 with a connecting element 101in a series connection is conceivable. In this case, an element to beconnected (which cannot, however, be seen) is screwed from above ontothe joining region 13. As a result, the cylindrical element 24 isshifted downward and the spring arms 25 are braced in an arcuate manner.The connecting element 1 is screwed here from above onto the connectingelement 101, and therefore the joining region 8 is screwed onto thejoining region 113. As a result, the cylindrical element 124 is shifteddownward and the spring arms 125 are braced in an arcuate manner. Thesecond connecting element 32 is likewise acted upon by the hollow pin 20and deformed and shifted. There is a fluidic connection from the joiningelement 13 as far as the joining element 118.

FIGS. 14 to 16 each show the upper end of the hollow pin 200, in whichthe opening differs in design in each case. In FIG. 14, the hollow pin200 has a cylindrical duct 201 which has by a slit formation 202provided transversely to the orientation of the duct, and therefore theopening in the duct not only takes place upward, but also to the side.

In FIG. 15, the hollow pin 200 has a cylindrical duct 201 which iscovered at its end by a cap 202, wherein openings 203 for the dischargeof the fluid are formed laterally and below the cap. The openings 203are spaced apart from one another by webs 204.

In FIG. 16, the hollow pin 200 likewise has a cylindrical duct 201 whichis covered at its end by a cap 205, wherein openings 206 for thedischarging of the fluid are formed laterally and extending upward intothe cap. The openings 206 are spaced apart from one another by webs 207.

FIG. 17 shows a further exemplary embodiment of a connecting element 301according to the invention in section.

The connecting element 301 is designed with a housing 302. The housing302 consists of at least two housing parts, wherein three housing parts303, 304, 305 are provided in this exemplary embodiment. The housingparts 303, 304 are formed connected to each other, for example welded oradhesively bonded to each other. The housing part 305 is inserted intothe housing part 303 and is also optionally connected there to thehousing part 303. Alternatively, the connection of the housing part 303to the housing part 305 can also be dispensed with, as couldcorrespondingly also be the case with the other exemplary embodiments.As the connection, adhesive bonding, welding or clamping or aninterlocking connection could be possible in all of the examples.

The first housing part 303 has a base 306 with an encircling wall 307protruding thereon at an angle of 90°. The wall 307 here is orientedsubstantially axially. This means that the wall is oriented in the axialdirection to the center axis 400, for example parallel thereto.

The base 305 is provided with the joining element 308. For this purpose,the joining element 308 is attached to the base 306 as a joining branch.Said joining element is advantageously connected or formed integrallywith the base 306. An element to be connected can be connected, forexample, screwed, here to the joining element 308. For this purpose, athread 310 is provided by means of which the element to be connected canbe screwed.

The housing part 303 has a tubular region 311 which protrudes from thebase 306 in the axial direction and protrudes from the base 306 in theopposite direction to the wall 307.

The tubular region 311 is arranged radially within the joining element308 and is embraced by the latter. The tubular region 311 also protrudesout of the joining element 308 in the axial direction.

The second housing part 304 is formed in the manner of a cover with abase 312, from which a joining branch 313 with a fluid opening 314extends upward in the axial direction, i.e. away from the receivingspace 316 which forms a chamber. A projection 315 is provided in theopposite direction, said projection engaging radially on the inside andin the axial direction into the wall 307. The projection 315 isadvantageously designed in a segmented manner and is distributed overthe circumference of the base 312 or alternatively is also of encirclingdesign.

As can be seen in FIG. 17, the two housing parts 303, 304 are connectedto each other, for example welded, on the end side of the wall 307.Alternatively, adhesive bonding, pressing together, clipping, etc. mayalso be useable.

The housing 302 forms a first receiving space 316, wherein saidreceiving space is arranged within the housing part 303 in the regionclosed off from the housing part 304. The receiving space 316 here issurrounded by the wall 307.

According to FIG. 17 and corresponding to FIGS. 6, 7, 11 and 12, thewall 307 is not of completely round design but rather has radiallyoutwardly protruding pockets 317 which serve for receiving spring armsof the valve element. The pockets 317 are designed as radially outwardlyprotruding regions of a circle, wherein the radius of the wall 307 issmaller between the pockets 317.

The third housing part 305 is arranged in the receiving space 316. Saidhousing part has a baseplate 319 and a hollow pin 320 which protrudestherefrom and has a continuous duct 321. At the upper end of the hollowpin, the hollow pin 320 has a type of cap, wherein an opening 322 isprovided laterally in order to allow fluid to flow in or out. The duct321 is open toward the second receiving space 323.

Furthermore, a valve element 318 is arranged in the receiving space 316.

The joining element 313 is provided upward on the base 312 of thehousing part 304, as already described above. If an element to beconnected to the joining element 313, such as, for example, a syringe orthe like, or a joining branch attached thereto, is inserted or screwedinto the joining element 313, a fluidic communication is intended to beable to take place between the element to be connected and the receivingspace 316. If an element to be connected is not inserted into thejoining element 313, the joining element 13 is intended to be closed offand sealed.

This is achieved by the valve element 318. The valve element 318 has acylindrical region 324 from which spring arms 325 protrude downward. Thecylindrical region 324 here is advantageously formed integrally with thespring arms 325 and the spring arms 325 protrude radially outward anddownward from the cylindrical region 324 at an angle of approximately45° to the vertical. If three spring arms 325 are present, the springarms 325 approximately form an arrangement in accordance with an edgearrangement of a tetrahedron.

The protruding spring arms 325 are advantageously designed as springarms 325 which are rectilinear or are kinked or curved once or multipletimes. In the exemplary embodiment of FIG. 17, the spring arms 325 aredesigned to be kinked twice.

For this purpose, the spring arms 325 have a first region 326 which isarranged at an angle α1 of approximately 25 to 30°, preferably 27°, tothe plane perpendicular to the longitudinal axis 400 of the cylindricalregion 324.

Furthermore, the spring arms 325 have a second region 327 which isarranged at an angle α2 of approximately 35 to 40°, preferably 37°, tothe plane perpendicular to the longitudinal axis 400 of the cylindricalregion 324. The spring arms also have a third region 328 which isarranged at an angle α3 of approximately 75 to 80°, preferably 77°, tothe plane perpendicular to the longitudinal axis 400 of the cylindricalregion 324.

The cylindrical region 324 has a duct 329 which is closed at its upperend by a wall formation 401. The cylindrical region 324 has there a slot330 which opens when the wall formation 401 is deformed.

If the slot 330 is closed, a fluidic connection between the joiningelement 313 and the receiving space 316 is prevented. If the slot 330 isopened, a fluidic connection between the joining element 313 and thereceiving space 316 is made possible.

If the valve element 318 is pressed downward in the axial direction byan element to be connected, the hollow pin 320 engages in the duct 329and deforms the cylindrical region 324 such that the slot is opened.

FIG. 17 shows that the duct 329 is of substantially cylindrical orconical design and extends in the axial direction. On its innercircumference, the duct 329 has two radially inwardly protruding annularsealing lips 402, 403 or sealing beads. Said sealing lips 402, 403protrude radially inward and bear against the hollow pin 320 and sealoff the latter. It can be seen in FIG. 17 that the sealing lip 403 isarranged above the opening 322 and the sealing lip 402 is arranged belowthe opening, and therefore the two sealing lips 402, 403 are arranged onboth sides, as viewed in the axial direction, of the opening 322 in thehollow pin.

As an alternative to the two sealing lips 402, 403, it is also possiblefor only one such sealing lip to be provided, or it is also possible formore than two such sealing lips to be provided.

In the positions of the valve element 315 that are shown in FIG. 17, afluidic connection between the joining element 313 and the receivingspace 316 is closed off and sealed. If an element is inserted from aboveinto the joining element 313, the cylindrical region 324 of the valveelement 318 is compressed and/or pushed downward such that the springarms 325 are supported on the edges of the pockets 317 and areelastically deformed. As a result, the cylindrical region 324 is shifteddownward and the fluidic connection is made possible by means of slot330 and duct 329 and the hollow pin.

If the element to be connected is removed again from the joining element307, the elastic moldable valve element 318 relaxes again and thecylindrical region 324 is pushed upward again, and therefore the joiningelement 313 is sealed again.

The interior of the connecting element 301 is divided by the base 319.The receiving space 323 which is of approximately cylindrical design isarranged below the base 319. The second valve element 331 with thecylindrical region 332 and the spring arms 333 is arranged in saidreceiving space 23. The spring arms are arranged between a flank of thefirst housing part and the base 319 and support the cylindrical region332 in the axial direction. If an element to be connected is screwedinto the joining region 308, the cylindrical region 332 of the secondvalve element is shifted upward axially counter to the restoring forceof the spring arms 333, wherein the cylindrical region 332 is alsodeformed. In the process, the lower sealing region 334 is released fromthe encircling bead 335 of the tubular region 311 and a fluid flow ispermitted.

Preferably, the elastic elements which are provided as valve elements318, 331 consist of an elastomeric material and the housing elements303, 304, 305 consist of a non-elastomeric, but rather dimensionallystable, material, such as of thermoplastic. The element 318 and theelement 331 here can preferably consist of liquid silicone rubber (LSR)or silicone rubber crosslinking at a high temperature (HTC) or siliconerubber crosslinking at room temperature (RTC), and the housing parts303, 304, 305 can consist of acrylonitrile/butadiene/styrene (ABS),polycarbonate (PC), polypropylene (PP) or polyethylene (PE) or the like.

1. Connecting element with a housing having a first receiving space witha first joining element and a first shiftable valve element arrangedtherein, and having a second receiving space with a second joiningelement with a second shiftable valve element arranged therein, thefirst and the second receiving space are fluidically connected to eachother, wherein the first valve element is of elastically deformabledesign and is shiftable, and the second valve element is of elasticallydeformable design and is shiftable, wherein the first valve element isshiftable between two positions, wherein, in the first position, afluidic connection between the first receiving space and the firstjoining element is interrupted by the first valve element and, in thesecond position, a fluidic connection between the first receiving spaceand the first joining element is opened by the first valve element, andwherein the second valve element is shiftable between two positions,wherein, in the first position, a fluidic connection between the secondreceiving space and the second joining element is interrupted by thesecond valve element and, in the second position, a fluidic connectionbetween the second receiving space and the second joining element isopened by the second valve element, wherein the first valve element isformed with a duct which is closed in the first position of the firstvalve element and is opened in the second position of the first valveelement, wherein a hollow pin is arranged in the first receiving spaceand engages in the duct.
 2. Connecting element with a housing having afirst receiving space with a first joining element and a first shiftablevalve element arranged therein, and having a second receiving space, thefirst and the second receiving space are fluidically connected to eachother, wherein the first valve element is of elastically deformabledesign and is shiftable, wherein the first valve element is shiftablebetween two positions, wherein, in the first position, a fluidicconnection between the first receiving space and the first joiningelement is interrupted by the first valve element and, in the secondposition, a fluidic connection between the first receiving space and thefirst joining element is opened by the first valve element, wherein thefirst valve element is formed with a duct which is closed in the firstposition of the first valve element and is opened in the second positionof the first valve element, wherein a hollow pin is arranged in thefirst receiving space and engages in the duct.
 3. Connecting elementaccording to claim 1, wherein the housing is of at least two-partdesign, wherein the at least two housing parts are advantageouslyconnected to each other, for example, in particular, are connected toeach other so as not to be releasable nondestructively.
 4. Connectingelement according to claim 3, wherein the first receiving space and thesecond receiving space are formed by a first and a second housing part,wherein the first housing part form the first receiving space and thesecond receiving space, wherein the second housing part bounds the firstreceiving space in the manner of a cover.
 5. Connecting elementaccording to claim 1, wherein the hollow pin is inserted as a thirdhousing part into the first or the second housing part.
 6. Connectingelement according to claim 1, wherein the third housing part forming thehollow pin is connected in an integrally bonded manner to the first orthe second housing part.
 7. Connecting element according to claim 1,wherein the hollow pin is formed integrally with the first or the secondhousing part, for example, in particular, is injection molded thereon.8. Connecting element according to claim 1, wherein the first joiningelement is arranged or formed on the first housing part and the secondjoining element is arranged or formed on the second housing part. 9.Connecting element according to claim 1, wherein the first receivingspace has a circular cross section in section and is bounded by anencircling wall, wherein the receiving space is bounded by twoapproximately flat wall regions, wherein the first joining element isarranged or received on one of the two walls and a fluidic connection tothe second receiving space is provided in the other wall.
 10. Connectingelement according to claim 1, wherein the first receiving space has acircular cross section in section with outwardly protruding pockets andis bounded by an encircling wall which is changeable in radius, whereinthe receiving space is bounded by two approximately flat wall regions,wherein the first joining element is arranged or received on one of thetwo walls and a fluidic connection to the second receiving space isprovided in the other wall.
 11. Connecting element according to claim 1,wherein the number of pockets is greater than or equal to the number ofspring arms of a valve element inserted into the receiving space. 12.Connecting element according to claim 11, wherein a spring arm of thevalve element is arranged in each pocket.
 13. Connecting elementaccording to claim 1, wherein the first joining element has ahollow-cylindrical element and the first valve element has at least onecylindrical region which is accommodated in a shiftable manner in thehollow-cylindrical element.
 14. Connecting element according to claim 1,wherein the first valve element has spring arms protruding at thecylindrical region.
 15. Connecting element according to claim 14,wherein the spring arms protrude from the cylindrical region in a mannersubstantially corresponding to the edges of a tetrahedron. 16.Connecting element according to claim 14, wherein the protruding springarms are designed as spring arms which are rectilinear or are kinked orcurved once or multiple times.
 17. Connecting element according to claim1, wherein the spring arms of the first valve element are arranged at anangle of 120° to one another in the plane perpendicular to thelongitudinal axis of the cylindrical region.
 18. Connecting elementaccording to claim 1, wherein the spring arms have a first region whichis arranged at an angle of approximately 25 to 30°, preferably 27°, tothe plane perpendicular to the longitudinal axis of the cylindricalregion.
 19. Connecting element according to claim 1, wherein the springarms have a second region which is arranged at an angle of approximately35 to 40°, preferably 37°, to the plane perpendicular to thelongitudinal axis of the cylindrical region.
 20. Connecting elementaccording to claim 1, wherein the spring arms have a third region whichis arranged at an angle of approximately 75 to 80°, preferably 77°, tothe plane perpendicular to the longitudinal axis of the cylindricalregion.
 21. Connecting element according to claim 1, wherein, in theevent of a load being applied to the cylindrical region, the spring armsare deformed in an arcuate manner such that the cylindrical regionsubstantially carries out an axial movement.
 22. Connecting elementaccording to claim 1, wherein the duct of the valve element is open onone side and is designed to be closeable on the opposite side with acloseable and openable slot.
 23. Connecting element according to claim1, wherein, in the unloaded state of the valve element, the hollow pinonly partially engages, if at all, in the duct and does not act upon theslot in the closed state, and therefore the duct is closed. 24.Connecting element according to claim 1, wherein, in the loaded state ofthe valve element, the hollow pin virtually completely engages in orreaches through the duct and acts upon or pushes through the slot, andtherefore the duct is opened.
 25. Connecting element according to claim1, wherein the second joining element has a hollow-cylindrical element.26. Connecting element according to at claim 1, wherein at least one thesecond joining element has a hollow-cylindrical element and the secondvalve element has at least one cylindrical region which is accommodatedin a shiftable and/or deformable manner in the hollow-cylindricalelement.
 27. Connecting element according to claim 1, wherein the secondvalve element has spring arms protruding at the cylindrical region. 28.Connecting element according to claim 27, wherein the spring armsprotrude from the cylindrical region in a manner substantiallycorresponding to the edges of a tetrahedron.
 29. Connecting elementaccording to claim 27, wherein the protruding spring arms are designedas spring arms which are rectilinear or are kinked or curved once ormultiple times.
 30. Connecting element according to claim 1, wherein thespring arms of the second valve element are arranged at an angle of 120°to one another in the plane perpendicular to the longitudinal axis ofthe cylindrical region.
 31. Connecting element according to claim 1,wherein the spring arms have a first region which is arranged inclinedat an angle of approximately 35 to 55° to the plane perpendicular to thelongitudinal axis of the cylindrical region.
 32. Connecting elementaccording to claim 1, wherein the spring arms have a second region whichis arranged in a plane perpendicular to the longitudinal axis of thecylindrical region.
 33. Connecting element according to claim 1,wherein, in the event of a load being applied to the cylindrical region,the spring arms are deformed in an arcuate manner such that thecylindrical region substantially carries out an axial movement. 34.Connecting element according to claim 1, wherein the cylindrical regionof the second valve element bends under a load.
 35. Connecting elementaccording to claim 1, wherein the end side of the second receiving spacehas a radially inwardly directed constriction against which the secondvalve element is positioned in a sealing manner in the unloaded state.36. Connecting element according to claim 1, wherein the first valveelement has, on its duct, at least one radially inwardly protrudingsealing lip, in particular two sealing lips, which can be positioned onthe hollow pin for sealing purposes.
 37. Elastic spring element as avalve element with a cylindrical body and spring arms protrudingtherefrom, wherein the spring element is manufactured from an elasticmaterial.
 38. Elastic spring element according to claim 37, wherein theprotruding spring arms are designed as spring arms which are kinked orcurved once or multiple times.
 39. Elastic spring element according toclaim 37, wherein the spring arms of the first valve element arearranged at an angle of 120° to one another in the plane perpendicularto the longitudinal axis of the cylindrical region.
 40. Elastic springelement according to claim 37, wherein the spring arms have a firstregion which is arranged at an angle of approximately 35 to 55° to aplane perpendicular to the longitudinal axis of the cylindrical region.41. Elastic spring element according to claim 37, wherein the springarms have a second region which is arranged in a plane perpendicular tothe longitudinal axis of the cylindrical region.
 42. Elastic springelement according to claim 37, wherein the cross section of a spring armis of round or oval or polygonal design.
 43. Elastic spring elementaccording to claim 42, wherein the cross section of the spring arm isoval, wherein the cross section has a smaller diameter in a planethrough the mean perpendicular of the spring element than in thedirection perpendicular thereto.
 44. Elastic spring element according toclaim 37, wherein the cylindrical body has an encircling sealing lip oran encircling sealing region at an end region which is arranged oppositethe spring arms.
 45. Elastic spring element according to claim 37,wherein the sealing lip or the sealing region is designed as anencircling step.
 46. Elastic spring element according to claim 37,wherein a duct is provided in the cylindrical body, said duct having atleast one radially inwardly protruding sealing lip, in particular twosealing lips, which can be positioned on the hollow pin for sealingpurposes.